Project description:E. coli growing in continuous culture under continuous UVA irradiation exhibits growth inhibition with a subsequent adaptation to the stress. Transcriptome analysis was performed during transient growth inhibition and in the UVA light-adapted growth state. The results indicate that UVA light induces stringent response and an additional response that includes the upregulation of the synthesis of valine, isoleucine, leucine, phenylalanine, histidine and glutamate. The induction of several SOS response-genes strongly points to DNA damage as a result of UVA exposure. The involvement of oxidative stress was observed with the induction of ahpCF. Taken together it supports the hypothesis of the production of reactive oxygen species by UVA light. In the UVA-adapted cell population strong repression of the acid tolerance response was found. We identified the enzyme chorismate mutase as a possible chromophore for UVA light-inactivation and found strong repression of the pyrBI operon and the gene mgtA encoding for an ATP dependent Mg2+ transporter. Furthermore, our results indicate that the role of RpoS may not be as important in the adaptation of E. coli to UVA light as it was implicated by previous results with starved cells, but that RpoS might be of crucial importance for the resistance under transient light exposure. Keywords: stress response

Project description:Ultraviolet A (UVA) radiation is the major fraction of UV radiation reaching the Earth’s surface; its harmful effects on microorganisms obey mainly to oxidative damage, with the consequent loss of bacterial viability. In this work, the global transcriptional response of Pseudomonas aeruginosa exposed to UVA was analyzed. P. aeruginosa is an opportunistic human pathogen, also present in terrestrial and aquatic environments; its high ubiquity and versatily obeys to a complex regulatory network wich allows it to adapt to stressful conditions. To conduct this study, the PAO1 strain was grown in under sublethal doses of UVA or in the dark up to early logarithmic phase, and total RNA was obtained and sequenced by the RNA-seq technique. The analysis of the results, taking as significant a factor change ≥ 2 between irradiated and control samples, indicated that a total of 298 genes were regulated by UVA, representing 5.36 % of the total P. aeruginosa genome; half of these were induced and the other half were repressed. Data obtained by the transcriptomic study were validated by using RT qPCR of selected genes. The results presented in this study suggest that one of the main UVA targets are proteins carrying [Fe-S] clusters since several genes involved in the processes of synthesis, trafficking and assembly of these structures were upregulated. The management of intracellular iron levels also seems to be a robust response to this stress factor. The strong induction of genes involved in denitrification led us to suggest that this pathway and/or reactive nitrogen species such as nitric oxide could have a role in the response to this radiation. DNA also demonstrated to be an important UVA target as observed by the induction of SOS, prohage and pyocins genes. On the other hand, the down-regulation of genes involved in the biosynthesis of PQS, a quorum sensing signal of P. aeruginosa with several functions, could be beneficial given its role as endogenous photosensitizer. The study of the effects of UVA radiation is interesting due to its ecological consequences in natural environments. In addition, taking into account the high sensitivity of P.aeruginosa to UVA radiation and the issues with using traditional antibacterial products by the intrinsec or acquired resistance of P. aeruginosa to these agents, specially in the case of biofilms, UVA studies could have important implications for human health, industrial facilities and environmental management.

Project description:The UVB component of the sunlight (290-320 nm) plays an important role in carcinogenesis through generation of high levels of bipyrimidine DNA photoproducts, while UVA (320-400 nm) has been associated with photoaging and tumor progression through generation of low, but continuous levels of DNA damage and oxidative stress. However, the contribution of UVA light to epidermal cell fate in the context of photoaging remains poorly understood. Here, by using proteomic analyses and biochemical assays for validation, we show that UVA induces proteome remodeling and senescence in primary keratinocytes, eliciting potent antioxidant and pro-inflammatory responses. As a model of early skin tumorigenesis during aging, immortalized non-malignant keratinocytes, bearing potentially oncogenic mutations and dysfunctional components of the senescent machinery , are resilient to UVA-induced stress, but are sensitive to paracrine oxidative stress and immune system activation induced by senescent neighboring keratinocytes. These observations reveal a new cellular mechanism by which UVA induces photoaging in the epidermis.

Project description:Long wavelength Ultraviolet (UVA-1) radiation causes oxidative stress that leads to the formation of noxious substances within the skin. As a defensive mechanism skin cells produce detoxifying enzymes and antioxidants when they detect modified molecules. We have recently shown that UVA-1 irradiation oxidizes the abundant membrane phospholipid 1-palmitoyl-2-arachidonoyl-sn-glycero-3-phosphorylcholine (PAPC), which then induced the synthesis of the stress response protein heme oxygenase 1 (HO-1) in dermal fibroblasts. Here we examined the effects of UVA-1 and (UV-) oxidized phospholipids on the global gene expression in human dermal fibroblasts. We identified a cluster of genes that were co-induced by UVA-1-oxidized PAPC and UVA-1 radiation. The cluster included HO-1, glutamate-cysteine ligase modifier subunit (GCLM), aldo-keto reductases-1-C1 and -C2 (AKR1C1, AKR1C2), and interleukin 8 (IL8). These genes are members of the cellular stress response system termed “antioxidant response” or “Phase II detoxification”. Accordingly, the regulatory regions of all these genes contain binding sites for NF-E2-related factor 2 (Nrf2), a major regulator of the antioxidant response. Both UVA-1 irradiation and treatment with oxidized lipids led to increased nuclear accumulation of Nrf2. Silencing expression of Nrf2 using siRNA or using cells and tissue from Nrf2-deficient mice, we show that the induction of the co-regulated genes was suppressed. Expression of other canonical UVA-1-induced genes, including cyclooxygenase 2 (Cox2) and interleukin 6 (IL6) was unaltered in the absence of Nrf2. Together, our data show that UVA-1-mediated lipid oxidation induces induction of antioxidant response genes, which is dependent on the redox-regulated transcription factor Nrf2. To activate Nrf2 is a major strategy for novel antioxidant drugs, the skin photo-adaptation (SPA) inducers. Our finding that specific uv-oxidized lipids act similar sheds a new (ultraviolet) light on the usually detrimental “image” of UV generated lipid mediators. Experiment Overall Design: we profiled global mRNA expression levels in human dermal fibroblasts that had been treated with either UVA-1 or oxidized lipids. To investigate the effect of oxidized phospholipids on gene regulation, we used two preparations, which differed in their degree of oxidation; the minimally oxidized UV-PAPC resulting from UVA-1 irradiation of PAPC, and air-oxidized PAPC (OxPAPC), which represents the full spectrum of oxidation products (Gruber 07) (Reis et al., 2005). We irradiated dermal fibroblasts with UVA-1 (40J/cm²) or treated them with UV-PAPC, OxPAPC or native PAPC (100µg/ml each). We analyzed global gene expression four hours after stimulation with gene arrays (Affymetrix U133A Plus 2.0 Gene Chips).

Project description:Long wavelength Ultraviolet (UVA-1) radiation causes oxidative stress that leads to the formation of noxious substances within the skin. As a defensive mechanism skin cells produce detoxifying enzymes and antioxidants when they detect modified molecules. We have recently shown that UVA-1 irradiation oxidizes the abundant membrane phospholipid 1-palmitoyl-2-arachidonoyl-sn-glycero-3-phosphorylcholine (PAPC), which then induced the synthesis of the stress response protein heme oxygenase 1 (HO-1) in dermal fibroblasts. Here we examined the effects of UVA-1 and (UV-) oxidized phospholipids on the global gene expression in human dermal fibroblasts. We identified a cluster of genes that were co-induced by UVA-1-oxidized PAPC and UVA-1 radiation. The cluster included HO-1, glutamate-cysteine ligase modifier subunit (GCLM), aldo-keto reductases-1-C1 and -C2 (AKR1C1, AKR1C2), and interleukin 8 (IL8). These genes are members of the cellular stress response system termed “antioxidant response” or “Phase II detoxification”. Accordingly, the regulatory regions of all these genes contain binding sites for NF-E2-related factor 2 (Nrf2), a major regulator of the antioxidant response. Both UVA-1 irradiation and treatment with oxidized lipids led to increased nuclear accumulation of Nrf2. Silencing expression of Nrf2 using siRNA or using cells and tissue from Nrf2-deficient mice, we show that the induction of the co-regulated genes was suppressed. Expression of other canonical UVA-1-induced genes, including cyclooxygenase 2 (Cox2) and interleukin 6 (IL6) was unaltered in the absence of Nrf2. Together, our data show that UVA-1-mediated lipid oxidation induces induction of antioxidant response genes, which is dependent on the redox-regulated transcription factor Nrf2. To activate Nrf2 is a major strategy for novel antioxidant drugs, the skin photo-adaptation (SPA) inducers. Our finding that specific uv-oxidized lipids act similar sheds a new (ultraviolet) light on the usually detrimental “image” of UV generated lipid mediators.

Project description:E. coli growing in continuous culture under continuous UVA irradiation exhibits growth inhibition with a subsequent adaptation to the stress. Transcriptome analysis was performed during transient growth inhibition and in the UVA light-adapted growth state. The results indicate that UVA light induces stringent response and an additional response that includes the upregulation of the synthesis of valine, isoleucine, leucine, phenylalanine, histidine and glutamate. The induction of several SOS response-genes strongly points to DNA damage as a result of UVA exposure. The involvement of oxidative stress was observed with the induction of ahpCF. Taken together it supports the hypothesis of the production of reactive oxygen species by UVA light. In the UVA-adapted cell population strong repression of the acid tolerance response was found. We identified the enzyme chorismate mutase as a possible chromophore for UVA light-inactivation and found strong repression of the pyrBI operon and the gene mgtA encoding for an ATP dependent Mg2+ transporter. Furthermore, our results indicate that the role of RpoS may not be as important in the adaptation of E. coli to UVA light as it was implicated by previous results with starved cells, but that RpoS might be of crucial importance for the resistance under transient light exposure. Slide microarrays were purchased from MWG-Biotech AG (Ebersberg, Germany). The MWG E. coli Array contains 4,288 gene specific oligonucleotide probes representing the complete E. coli K12 genome. Microarray slides were scanned using the Affymetrix 428TM Array Scanner (High Wycombe, UK). Spot intensities and corresponding background signals were quantified with the Affymetrix JaguarTM software version 2.0. Further data analysis was performed with the program GeneSpring from Silicon Genetics (Redwood City, CA, USA). Induction factors (IF) were calculated from the Cy3 and Cy5 signal intensities of the spot. Spots with signal intensity below a value of 50 were excluded from the analysis and the minimal induction factor was set to 0.01. The normalization was performed with the 50th percentile distribution of remaining spots after background correction. The mean value of the IF of a specific gene was calculated from three replicates. Biological experiments were carried out three times, which provided three biological repeats. Dye swapping was performed for one replicate and did not alter the result.

Project description:Ultraviolet light is the dominant environmental oxidative skin stressor and a major skin aging factor. We studied which oxidized phospholipid (OxPL) mediators Ultraviolet A (UVA) would generate in primary human keratinocytes (KC). Mass spectrometric analysis of the oxidized phospholipidome of KC immediately or 24h post stress revealed dynamic changes in abundance of 174 oxidized phosphocholine species. Exposure to UVA and to in vitro UVA - oxidized phospholipids both activated, on transcriptome and proteome level, NRF2/antioxidant response signaling and lipid metabolizing enzyme expression, whereas UVA additionally initiated the unfolded protein response (UPR). We identified Nupr1 as an upstream transcriptional regulator of UVA/OxPL mediated gene expression that is itself transcriptionally regulated by reactive lipids, which also aggregate and crosslink recombinant Nupr1 protein. Nupr1 governs the basal and stress regulated expression of cell cycle, redox reactive, autophagy- and lipid metabolizing genes in epidermal keratinocytes, making it a potential key factor in skin ROS responses, -aging and -pathology.

Project description:The presence of melanopsin (OPN4) has been shown in cultured murine melanocytes and was associated with ultraviolet A radiation (UVA) reception. We demonstrated the protective role of OPN4 in skin physiology and the increased UVA-induced damage in its absence using proteomics analysis.

Project description:The presence of melanopsin (OPN4) has been shown in cultured murine melanocytes and was associated with ultraviolet A radiation (UVA) reception. We demonstrated the protective role of OPN4 in skin physiology and the increased UVA-induced damage in its absence, using proteomics analysis.

Project description:The presence of melanopsin (OPN4) has been shown in cultured murine melanocytes and was associated with ultraviolet A radiation (UVA) reception. We demonstrated the protective role of OPN4 in skin physiology and the increased UVA-induced damage in its absence using proteomics analysis.